Chapter 16

Acid-Base Equilibria

Chemistry, The Central Science, 11th edition

Theodore L. Brown; H. Eugene LeMay, Jr.;

Bruce E. Bursten; Catherine J. Murphy

Ahmad Aqel IfseisiAssistant Professor of Analytical Chemistry

College of Science, Department of Chemistry

King Saud University

P.O. Box 2455 Riyadh 11451 Saudi Arabia

Building: 05, Office: AA53

Tel. 014674198, Fax: 014675992

Web site: http://fac.ksu.edu.sa/aifseisi

E-mail: ahmad3qel@yahoo.com

aifseisi@ksu.edu.sa

Acids and bases are important in numerous chemical processes

that occur around us – from industrial processes to biological

ones, from reactions in the laboratory to those in our environment.

The time required for a metal object immersed in water to

corrode, the ability of an aquatic environment to support fish and

plant life, the fate of pollutants washed out of the air by rain, and

even the rates of reactions that maintain our lives all critically

depend upon the acidity or basicity of solutions.

Indeed, an enormous amount of chemistry can be understood in

terms of acid-base reactions.

16.1

Acids and Bases: A Brief

Review

Arrhenius Definition

An acid is a substance that, when dissolved in water, increases the

concentration of hydrogen ions (H+).

HCl(g) → H+(aq) + Cl-

(aq)

A base is a substance that, when dissolved in water, increases the

concentration of hydroxide ions (OH-).

NaOH(s) → Na+(aq) + OH-

(aq)

16.2

Brønsted-Lowry Acids and

Bases

Brønsted-Lowry

An acid is a proton donor.

A base is a proton acceptor.

Brønsted-Lowry Definition

When a proton is transferred from HCl to H2O, HCl acts as the Brønsted-Lowry

acid and H2O acts as the Brønsted-Lowry base.

What happens when an acid dissolves in water?

Water acts as a Brønsted-Lowry base and abstracts a proton (H+) from the acid.

As a result, the conjugate base of the acid and a hydronium ion are formed.

The Arrhenius concept of acids and bases, while useful, has limitations. For one

thing, it is restricted to aqueous solutions.

Brønsted-Lowry concept is based on the fact that acid-base reactions involve the

transfer of H+ ions from one substance to another.

A Brønsted-Lowry acid…

…must have a removable (acidic) proton

A Brønsted-Lowry base…

…must have a pair of nonbonding electrons

An H+ ion is simply a proton with no surrounding valence electron.

This small, positively charged particle interacts strongly with the

nonbonding electron pairs.

Water molecules to form hydrated hydrogen ions. For example, the interaction of a

proton with one water molecule forms the hydronium ion, H3O+(aq)

Chemists use H+(aq) and H3O+(aq) interchangeably to represent the same thing –

namely the hydrated proton that is responsible for the characteristic properties of

aqueous solutions of acids.

Because the emphasis in the Brønsted-Lowry concept is on proton transfer, the

concept also applies to reactions that do not occur in aqueous solution. In the

reaction between HCl and NH3, for example, a proton is transferred from the acid

HCl to the base NH3.

Ammonia is an Arrhenius base because adding it to water leads to an increase in

the concentration of OH-(aq). It is a Brønsted-Lowry base because it accepts a

proton from H2O. The H2O molecule in the equation acts as a Brønsted-Lowry

acid because it donates a proton to the NH3 molecule.

An acid and a base always work together to transfer a proton. In other words, a

substance can function as an acid only if another substance simultaneously

behaves as a base.

-To be a Brønsted-Lowry acid, a molecule or ion must have a hydrogen atom that

it can lose as an H+ ion.

-To be a Brønsted-Lowry base, a molecule or ion must have a nonbonding pair of

electrons that it can use to bind the H+ ion.

e.g., HCO3-, HSO4

-, H2O

Some substances can act as an acid in one reaction and as a

base in another.

For example, H2O is a Brønsted-Lowry base in its reaction with

HCl and a Brønsted-Lowry acid in its reaction with NH3.

A substance that is capable of acting as either an acid or a base is

called amphiprotic.

An amphiprotic substance acts as a base when combined with

something more strongly acidic than itself and an acid when

combined with something more strongly basic than itself.

Conjugate Acids and Bases

In the forward reaction HX donates a proton to H2O. Therefore, HX is the Brønsted-

Lowry acid, and H2O is the Brønsted-Lowry base. In the reverse reaction the H3O+

ion donates a proton to the X- ion, so H3O+ is the acid and X- is the base. When the

acid HX donates a proton, it leaves X- which can act as a base. Likewise, when

H2O acts as a base, it generates H3O+, which can act as an acid.

An acid and a base such as HX and X- that differ only in the presence or absence

of a proton are called a conjugate acid-base pair.

-Every acid has a conjugate base, formed by removing a proton from the acid, for

example, OH- is the conjugate base of H2O, and X- is the conjugate base of HX.

-Every base has associated with it a conjugate acid, formed by adding a proton to the

base. Thus, H3O+ is the conjugate acid of H2O, and HX is the conjugate acid of X-.

Sample Exercise 16.1 Identifying Conjugate Acids and Bases

(a) What is the conjugate base of each of the following acids: HClO4, H2S, PH4+, HCO3

–?

(b) What is the conjugate acid of each of the following bases: CN–, SO42–, H2O, HCO3

– ?

Write the formula for the conjugate acid of each of the following: HSO3–, F– , PO4

3–, CO.

Answers: H2SO3, HF, HPO42–, HCO+

Practice Exercise

Solution

(a) HClO4 less one proton (H+) is ClO4–. The other conjugate bases are HS–, PH3, and

CO32–.

(b) CN– plus one proton (H+) is HCN. The other conjugate acids are HSO4–, H3O

+, and

H2CO3.

Notice that the hydrogen carbonate ion (HCO3–) is amphiprotic. It can act as either an acid

or a base.

Sample Exercise 16.2 Writing Equations for Proton-Transfer Reactions

The hydrogen sulfite ion (HSO3–) is amphiprotic. (a) Write an equation for the reaction

of HSO3– with water, in which the ion acts as an acid. (b) Write an equation for the

reaction of HSO3– with water, in which the ion acts as a base. In both cases identify the

conjugate acid–base pairs.

Solution

The conjugate pairs in this equation are HSO3– (acid) and SO3

2– (conjugate base); and H2O (base)

and H3O+ (conjugate acid).

The conjugate pairs in this equation are H2O (acid) and OH– (conjugate base), and HSO3– (base)

and H2SO3 (conjugate acid).

Acid and Base Strength

Strong acids are completelydissociated in water.Their conjugate bases are quite weak.

Weak acids only dissociate partiallyin water.Their conjugate bases are weak bases.

Substances with negligible aciditydo not dissociate in water.Their conjugate bases are exceedinglystrong.

Example:CH4 contains hydrogen but does notdemonstrate any acidic behavior inwater. Its conjugate base (CH3

-) is astrong base.

In any acid-base reaction, the equilibrium will favor the reaction that moves the

proton to the stronger base.

H2O is a much stronger base than Cl-, so the equilibrium lies so far to the right that

K is not measured (K >> 1).

Acetate CH3COO- is a stronger base than H2O, so the equilibrium favors the left

side (K < 1).

-The stronger an acid, the weaker is its conjugate base.

-The stronger a base, the weaker is its conjugate acid.

Sample Exercise 16.3 Predicting the Position of a Proton-Transfer Equilibrium

For the following proton-transfer reaction, use Acid-Base strength Figure to predict whether the

equilibrium lies predominantly to the left (that is, Kc < 1 ) or to the right (Kc > 1):

Solution

CO32– appears lower in the right-hand column in the Figure and is therefore a stronger base than

SO42–. CO3

2–, therefore, will get the proton preferentially to become HCO3–, while SO4

2– will

remain mostly unprotonated. The resulting equilibrium will lie to the right, favoring products (that

is, Kc > 1).

Comment: Of the two acids in the equation, HSO4– and HCO3

–, the stronger one gives up a

proton more readily while the weaker one tends to retain its proton. Thus, the equilibrium favors

the direction in which the proton moves from the stronger acid and becomes bonded to the

stronger base.

16.3

The Autoionization of Water

H2O (l) + H2O (l) H3O+ (aq) + OH- (aq)

This is referred to as autoionization of water.

Autoionization of Water

Depending on the circumstances, water can act as either a Brønsted acid or a

Brønsted base (water is amphoteric). In the presence of an acid, water acts as a

proton acceptor; in the presence of a base, water acts as a proton donor. In fact,

one water molecule can donate a proton to another water molecule.

In pure water, a few molecules act as bases and a few act as acids.

At room temperature only about two out of every 109 molecules are ionized at any

given instant. Thus, pure water consists almost entirely of H2O molecules and is

an extremely poor conductor of electricity. Nevertheless, the autoionization of

water is very important.

The Ion-Product Constant of Water

H2O (l) + H2O (l) H3O+ (aq) + OH- (aq)

The equilibrium expression for this process is

Kc = [H3O+] [OH-]

This special equilibrium constant is referred to as the ion-product constant for

water, Kw.

The term [H2O] is excluded from the equilibrium-constant expression because we

exclude the concentration of pure solids and liquids.

Kw = [H3O+][OH-] = [H+][OH-] = 1.0 x 10-14 (at 25 oC)

What makes this Equation particularly useful is that it is applicable to pure

water and to any aqueous solution. Although the equilibrium between H+(aq)

and OH-(aq) as well as other ionic equilibria are affected somewhat by the

presence of additional ions in solution.

A solution in which [H+] = [OH-] is said to be neutral.

In most solutions H+ and OH- concentrations are not equal. As the

concentration of one of these ions increases, the concentration of the other

must decrease, so that the product of their concentrations equals 1.0 x 10-14.

In acidic solutions [H+] exceeds [OH-].

In basic solutions [OH-] exceeds [H+].

Kw = [H3O+][OH-] = [H+][OH-] = 1.0 x 10-14 (at 25 oC)

Sample Exercise 16.4 Calculating [H+] for Pure Water

Calculate the values of [H+] and [OH-] in a neutral solution at 25 ºC.

Indicate whether solutions with each of the following ion concentrations are neutral, acidic, or

basic:

(a) [H+] = 4 × 10–9 M ; (b) [OH–] = 1 × 10–7 M ; (c) [OH–] = 7 × 10–13 M .

Answers: (a) basic, (b) neutral, (c) acidic.

Practice Exercise

Solution

We will represent the concentration of [H+] and [OH–] in neutral solution with x. This gives

In an acid solution [H+] is greater than ; 1.0 × 10–7 M in a basic solution [H+] is less than 1.0 × 10–7 M.

Sample Exercise 16.5 Calculating [H+] from [OH-]

Calculate the concentration of H+(aq) in;

(a) a solution in which [OH–] is 0.010 M, (b) a solution in which [OH–] is 1.8 ×10–9 M .

Note: In this problem and all that follow, we assume, unless stated otherwise, that the

temperature is 25 ºC.

Solution

(a) Using Equation 16.14, we

have:

This solution is basic because

(b) In this instance

This solution is acidic because

16.4

The pH Scale

pH is defined as the negative logarithm in base 10 of the concentration of

hydronium ion.

pH

pH = -log [H3O+] or pH = -log [H+]

• In pure water,

Kw = [H3O+] [OH-] = 1.0 10-14

• Since in pure water [H3O+] = [OH-],

[H3O+] = 1.0 10-14 = 1.0 10-7

• Therefore, in pure water,

pH = -log (1.0 10-7) = 7.00

• An acid has a higher [H3O+] than pure water, so its pH is <7.

• A base has a lower [H3O+] than pure water, so its pH is >7.

Because of the negative sign in Equation (pH = -log[H+]),

the pH decreases as [H+] increases.

A sample of freshly pressed apple juice has a pH of 3.76, calculate [H+]

pH = -log[H+] = 3.76

Log[H+] = -3.76

[H+] = antilog(-3.76) = 10-3.76 = 1.7 x 10-4 M

Examples …

[H+] = 1.0 x 10-3 M calculate pH

pH = -log(1.0 x 10-3) = - (-3.00) = 3

These are the pH

values for several

common substances at

25 oC.

The pH of a solution

can be estimated using

the benchmark

concentrations of H+

and OH- corresponding

to whole number pH

values.

Sample Exercise 16.6 Calculating pH from [H+]

Calculate the pH values for;

(a) a solution with [OH–] is 0.010 M, (b) a solution with [OH–] is 1.8 ×10–9 M .

Solution

(a) In the first instance we found [H+], to be 1.0 ×10–12 M.

Because 1.0 ×10–12 has two significant figures, the pH has two decimal places, 12.00.

(b) [H+] = 5.6 × 10–6 M. Before performing the calculation, it is helpful to estimate the

pH. To do so, we note that [H+] lies between 1 × 10–6 and 1 × 10–5

Thus, we expect the pH to lie between 6.0 and 5.0.

Sample Exercise 16.7 Calculating [H+] from pH

A sample of freshly pressed apple juice has a pH of 3.76. Calculate [H+].

Solution

From Equation 16.17, we have

Thus,

To find [H+] , we need to determine the

antilog of –3.76. Scientific calculators

have an antilog function (sometimes

labeled INV log or 10x) that allows us

to perform the calculation:

Comment: Consult the user’s manual for your calculator to find out how to perform the antilog

operation. The number of significant figures in [H+] is two because the number of decimal places

in the pH is two.

pOH and Other “p” Scales

• The “p” in pH tells us to take the negative base -10 logarithm of the

quantity (in this case, hydronium ions).

• Some similar examples are

– pOH = -log [OH-]

– pKw = -log Kw

Because

[H3O+] [OH-] = Kw = 1.0 10-14

we know that

-log [H3O+] + -log [OH-] = -log Kw = 14.00

or, in other words,

pH + pOH = pKw = 14.00

px = -logxLarger the x, smaller the px

Measuring pH

For accurate measurements, one

uses a pH meter, which measures

the voltage in the solution.

The device is a millivoltmeter, and

the electrodes immersed in the

solution being tested produce a

voltage that depends on the pH of

the solution.

A voltage (in millivolts), which varies with the pH, is generated when the

electrodes are placed in a solution. This voltage is read by the meter, which is

calibrated to give pH.

– Litmus paper• “Red” paper turns blue above ~pH = 8

• “Blue” paper turns red below ~pH = 5

– Universal indicator papersPapers impregnated with several indicators.

– Indicators: special chemicals that change color if there is a change in the pH

(caused by adding an acid or alkali). Indicators change color at different pH values.

For less accurate measurements, one can use

The pH ranges

for the color

changes of some

common acid-

base indicators.

Most indicators

have a useful

range of about 2

pH units.

Methyl orange changes color over the pH interval from 3.1 to 4.4. Below

pH 3.1 it is in the acid form (red). In the interval between 3.1 and 4.4, it is

gradually converted to its basic form, which has a yellow color. By pH 4.4

the conversion is complete, and the solution is yellow.

16.5

Strong Acids and Bases

• The seven most common strong acids are HCl, HBr, HI, HNO3,HClO3, and HClO4 (monoprotic) and H2SO4 (diprotic).

• These are, by definition, strong electrolytes and exist totally as ionsin aqueous solution.

• For the monoprotic strong acids,

[H3O+] or [H+] = [acid]

Strong acids are strong electrolytes, existing in aqueous solution entirely as ions.

For example,

Sample Exercise 16.8 Calculating the pH of a Strong Acid

What is the pH of a 0.040 M solution of HClO4?

Solution

The pH of the solution is given by

pH = –log(0.040) = 1.40.

Check: Because [H+] lies between 1 × 10–2 and 1 × 10–1, the pH will be

between 2.0 and 1.0. Our calculated pH falls within the estimated range.

Furthermore, because the concentration has two significant figures, the pH has

two decimal places.

• Strong bases are the soluble hydroxides, which are the

alkali metal (group 1A) hydroxides (Na+1 and K+1) and

heavier alkaline earth metal (group 2A) hydroxides (Ca2+,

Sr2+, and Ba2+).

• Again, these substances dissociate completely in aqueous

solution.

Strong bases are strong electrolytes, existing in aqueous solution

entirely as ions.

For example,

Sample Exercise 16.9 Calculating the pH of a Strong Base

What is the pH of (a) a 0.028 M solution of NaOH, (b) a 0.0011 M solution of Ca(OH)2?

Solution

(a) NaOH dissociates in water to give one OH– ion per formula unit. Therefore, the OH– concentration

for the solution in (a) equals the stated concentration of NaOH, namely 0.028 M.

(b) Ca(OH)2 is a strong base that dissociates in water to give two OH– ions per formula unit. Thus, the

concentration of OH–(aq) for the solution in part (b) is 2 × (0.0011 M) = 0.0022 M

Although all the hydroxides of the alkali metals (group 1A) are strong electrolytes,

LiOH, RbOH, and CsOH are not commonly encountered in the laboratory. The

hydroxides of the heavier alkaline earth metals Ca(OH)2, Sr(OH)2, and Ba(OH)2,

are also strong electrolytes. They have limited solubilities, however, so they are

used only when high solubility is not critical.

Another strong bases include the oxide ion. Ionic metal oxides, especially Na2O

and CaO, are often used in industry when a strong base is needed. The O2- reacts

with water to form OH-, leaving virtually no O2- remaining in the solution:

Thus, a solution formed by dissolving 0.010 mol of Na2O(s) in enough water to form

1.0 L of solution will have [OH-] = 0.020 M and a pH of 12.30.

16.6

Weak Acids

Dissociation Constants

• For a generalized acid dissociation,

or

This equilibrium constant Ka is called the acid-dissociation constant. Because

H2O is the solvent, it is omitted from the equilibrium-constant expression.

Most acidic substances are weak acids and are therefore only partially ionized in

aqueous solution. We can use the equilibrium constant for the ionization reaction to

express the extent to which a weak acid ionizes.

Either of the following ways, depending on whether the hydrated proton is

represented as H3O+(aq) or H+(aq):

The magnitude of Ka indicates the tendency of the acid to ionize in water, the larger the

value of Ka, the stronger the acid. Hydrofluoric acid (HF), for example, is the strongest acid

listed in Table, and phenol (HOC6H5) is the weakest.

In almost all cases the hydrogen atoms bonded to carbon do not ionize in water; instead, the

acidic behavior of these compounds is due to the hydrogen atoms attached to oxygen atoms.

Sample Exercise 16.10 Calculating Ka from Measured pH

A student prepared a 0.10 M solution of formic acid (HCOOH) and measured its pH. The pH at 25 ºC was found to

be 2.38. Calculate Ka for formic acid at this temperature.

Solution

Percent Ionization

The stronger the acid, the greater is the percent ionization.

For any acid, the concentration of acid that undergoes ionization equals the

concentration of H+(aq) that forms, assuming that the autoionization of water is

negligible.

For example, a 0.035 M solution of HNO2 contains 3.7 x 10-3 M H+(aq). Thus, the

percent ionization is

The magnitude of Ka indicates the strength of a weak acid. Another measure of

acid strength is percent ionization, which is defined as

Sample Exercise 16.11 Calculating Percent Ionization

A 0.10 M solution of formic acid (HCOOH) contains 4.2 × 10–3 M H+(aq).

Calculate the percentage of the acid that is ionized.

Solution

Calculating pH from Ka

Calculate the pH of a 0.30 M solution of acetic acid, HC2H3O2, at 25 C.

Ka for acetic acid at 25 C is 1.8 10-5.

Sample Exercise 16.12 Using Ka to Calculate pH

Calculate the pH of a 0.20 M solution of HCN (Ka = 9.9 × 10-6).

Solution

The properties of the acid solution that relate directly to the concentration of H+(aq).

The Figures compare the behavior of 1 M CH3COOH and 1 M HCl. The 1 M

CH3COOH contains only 0.004 M H+(aq), whereas the 1 M HCl solution contains 1

M H+(aq). As a result, the rate of reaction is much faster for the solution of HCl.

(a) the flask on the left

contains 1 M CH3COOH, the

one on the right contains 1 M

HCl with the same amount of

magnesium metal.

(b) when the Mg is dropped

into the acid, H2 gas is

formed. The rate of H2

formation is higher for HCl

on the right. Eventually, the

same amount of H2 forms in

both cases.

Sample Exercise 16.13 Using Ka to Calculate Percent Ionization

Calculate the percentage of HF molecules ionized in (a) a 0.10 M HF solution, (b) a 0.010 M HF solution.

Solution(a)

(b)

Polyprotic Acids

In the preceding example Ka2 is much smaller than Ka1.

It is always easier to remove the first proton from a polyprotic acid than to

remove the second.

Similarly, for an acid with three ionizable protons, it is easier to remove the second

proton than the third. Thus, the Ka values become successively smaller as

successive protons are removed.

Polyprotic acids have more than one ionizable H atom

The acid dissociation constants for these equilibria are labeled Ka1 and Ka2.

Because Ka1 is so much larger than subsequent dissociation constants for thesepolyprotic acids, most of the H+(aq) in the solution comes from the first ionizationreaction. As long as successive Ka values differ by a factor of 103.

If the difference between the Ka1 for the first dissociation and subsequent Ka2 valuesis 103 or more, the pH generally depends only on the first dissociation.

Sulfuric acid is strong acid with respect to the removal of the first proton. Thus, the

reaction for the first ionization step lies completely to the right:

HSO4-, on the other hand, is a weak acid for which Ka2 = 1.2 x 10-2.

Sample Exercise 16.14 Calculating the pH of a Polyprotic Acid Solution

The solubility of CO2 in pure water at 25 ºC and 0.1 atm pressure is 0.0037 M. The common practice is to assume that all

of the dissolved CO2 is in the form of carbonic acid (H2CO3), which is produced by reaction between the CO2 and H2O:

What is the pH of a 0.0037 M solution of H2CO3?

Solution

16.7

Weak Bases

Bases react with water to produce hydroxide ion.

Many substances behave as weak bases in water. Weak bases react with

water, abstracting protons from H2O, thereby forming the conjugate acid

of the base and OH- ions.

The constant Kb is called the base-dissociation constant. The constant

Kb always refers to the equilibrium in which a base reacts with H2O to

form the corresponding conjugate acid and OH-.

The equilibrium constant expression for this reaction can be written as

The equilibrium constant expression for this reaction is

[NH4+] [OH-]

[NH3]Kb =

These bases contain one or more lone pairs of electrons because a lone pair is necessary to

form the bond with H+. Notice that in the neutral molecules in the Table, the lone pairs are on

nitrogen atoms. The other bases listed are anions derived from weak acids.

Lists the names, formulas, Lewis structures, equilibrium reactions and values of Kb for several weak bases in water.

Sample Exercise 16.15 Using Kb to Calculate OH¯

Calculate the concentration of OH– in a 0.15 M solution of NH3.

Solution

Weak bases fall into two categories:

-The first category contains neutral substances that have an atom with a

nonbonding pair of electrons that can serve as a proton acceptor. Most of these

bases contain a nitrogen atom. These substances include ammonia and a related class

of compounds called amines.

The chemical formula for the conjugate acid of methylamine is usually written CH3NH3+.

-The second general category of weak bases consists of the anions of weak acids.

For example, NaClO dissociates to give Na+ and ClO- ions. Na+ ion is a spectator ion.

ClO- ion is the conjugate base of a weak acid, hypochlorous acid HClO. Consequently,

the ClO- ion acts as a weak base in water:

Types of Weak Bases

Sample Exercise 16.16 Using pH to Determine the Concentration of a Salt

A solution made by adding solid sodium hypochlorite (NaClO) to enough water to make 2.00 L of

solution has a pH of 10.50. Calculate the number of moles of NaClO that were added to the water.

(Kb = 3.3 × 10-7).

Solution

16.8

Relationship Between Ka

and Kb

Ka and Kb are related in this way:

Ka Kb = Kw

Therefore, if you know one of them, you can calculate the other.

To see if we can find a corresponding quantitative relationship, lets consider the

NH4+ and NH3 conjugate acid-base pair. Each of these species reacts with water:

This relationship is so important that it should receive special attention:

The product of the acid-dissociation constant for an acid and the base-

dissociation constant for its conjugate base equals the ion-product

constant for water.

As the strength of an acid increases (larger Ka), the strength of its

conjugate base must decrease (smaller Kb) so that the product Ka x Kb

equals 1.0 x 10-14 at 25 oC. Remember, this important relationship applies

only to conjugate acid-base pairs.

Last Equation can be written in terms of pKa and pKb by taking the

negative log of both sides:

Sample Exercise 16.17 Calculating Ka or Kb for a Conjugate Acid-Base Pair

Calculate (a) the base-dissociation constant, Kb, for the fluoride ion (F–);

(b) the acid-dissociation constant, Ka, for the ammonium ion (NH4+).

Solution

(a) Ka for HF = 6.8 × 10-4. We can calculate Kb for the conjugate base, F–:

(b) Kb for NH3 = 1.8 × 10-5. we can calculate Ka for the conjugate acid, NH4+ :

- Ka for the weak acid HF, Ka= 6.8 × 10-4.

- Kb for weak base NH3, Kb = 1.8 × 10-5.

16.9

Acid-Base Properties of Salt

Solutions

Ions can also exhibit acidic or basic properties.

Salt solutions can be acidic or basic.

Because nearly all salts are strong electrolytes, we can

assume that when salts dissolve in water, they are completely

dissociated.

Consequently, the acid-base properties of salt solutions are due to

the behavior of their constituent cations and anions.

Many ions are able to react with water to generate H+(aq) or OH-

(aq).

This type of reaction is often called hydrolysis. The pH of an

aqueous salt solution can be predicted qualitatively by considering

the ions of which the salt is composed.

Effect of Cation and Anion in Solution

1. An anion that is the conjugate base of a strong acid will not affect the pH.

2. An anion that is the conjugate base of a weak acid will increase the pH.

3. Cations of the strong bases will not affect the pH.

4. A cation that is the conjugate acid of a weak base will decrease the pH.

4. When a solution contains both the conjugate base of a weak acid and theconjugate acid of a weak base, the affect on pH depends on the Ka and Kb

values:• If Ka > Kb, the ion will cause the solution to be acidic.

• If Kb > Ka, the solution will be basic.

A+ + H2O AOH + H+

B- + H2O BH + OH-

(a) NaCl solution is neutral (pH =7.0)

(b) NH4Cl solution is acidic (pH = 3.5)

(c) NaClO solution is basic (pH = 9.5)

Salt solutions can be neutral, acidic, or basic. These three solutions contain the

acid-base indicator bromthymol blue.

This Figure demonstrates the influence of several salts on pH.

We can summarize the chapter as follows:

For strong acid and bases, they will be completely ionize to 100%.

For weak acids and bases we can use the dissociation constants, ka

and kb to find the amount that has been dissociated.

For salts when they dissolve in water (H+)(OH-), they can produce

acidic or basic solutions based on the type the reaction of the anion

and the cations of the salt with (H+) or (OH-) of the water:

- If the anion in the salt is a conjugate base of strong acid such as HCl, the acid

will not form in this direction and consequently the (H+) will not form and no

change in pH will result.

- If the anion salt is a conjugate base of weak acids such as acetic acid, the acid

will form and the hydroxide ions will form as well (OH-) giving basic solution.

- For the cation in the salt if it is a cation of the 1st or 2nd A groups, they will not

affect the pH but if they are transition metals, they will abstract the (OH-) ions

from water and result in formation of (H+) ions leading to acidic solution. Such

effect will depend on the dissociation constants.

Sample Exercise 16.18 Determining Whether Salt Solutions Are Acidic, Basic, or

Neutral

Determine whether aqueous solutions of each of the following salts will be acidic, basic, or neutral:

(a) Ba(CH3COO)2, (b) NH4Cl, (c) CH3NH3Br, (d) KNO3, (e) Al(ClO4)3.

Solution

(a) This solution contains barium ions and acetate ions. The cation, Ba2+, is an ion of one of the heavy

alkaline earth metals and will therefore not affect the pH. The anion, CH3COO–, is the conjugate base of the

weak acid CH3COOH and will hydrolyze to produce OH– ions, thereby making the solution basic.

(b) This solution contains NH4+ and Cl– ions. NH4

+ is the conjugate acid of a weak base (NH3) and is

therefore acidic. Cl– is the conjugate base of a strong acid (HCl) and therefore has no influence on the pH

of the solution. Because the solution contains an ion that is acidic (NH4+) and one that has no influence on

pH (Cl–), the solution of NH4Cl will be acidic.

(c) This solution contains CH3NH3+ and Br– ions. CH3NH3

+ is the conjugate acid of a weak base (CH3NH2,

an amine) and is therefore acidic. is the conjugate base of a strong acid (HBr) and is therefore pH-neutral.

Because the solution contains one ion that is acidic and one that is neutral, the solution of CH3NH3Br will

be acidic.

(d) This solution contains the K+ ion, which is a cation of group 1A, and the ion NO3–, which is the

conjugate base of the strong acid HNO3. Neither of the ions will react with water to any appreciable extent,

making the solution neutral.

(e) This solution contains Al3+ and ClO4– ions. Cations, such as Al3+, that are not in groups 1A or 2A are

acidic. The ClO4– ion is the conjugate base of a strong acid (HClO4) and therefore does not affect pH. Thus,

the solution of Al(ClO4)3 will be acidic.

Sample Exercise 16.19 Predicting Whether the Solution of an Amphiprotic Anion

is Acidic or Basic

Predict whether the salt Na2HPO4 will form an acidic solution or a basic solution on

dissolving in water.

Solution

The reaction with the larger equilibrium constant will determine whether the solution is acidic or basic

The value of Ka for Equation 16.45, is 4.2 × 10-13 .

We must calculate the value of Kb for Equation 16.46 from the value of Ka for its conjugate acid, H2PO4–.

We want to know Kb for the base HPO42–, knowing the value of Ka for the conjugate acid HPO4

2–:

Because Ka for H2PO4– is 6.2 × 10-8, we calculate Kb for HPO4

2– to be 1.6 × 10-7. This is more than 105 times

larger than Ka for H2PO42–; thus, the reaction shown in Equation 16.46 predominates over that in Equation

16.45, and the solution will be basic.

Q & A

A Brønsted–Lowry acid is:

a. a proton donor.

b. a proton acceptor.

c. an electron-pair donor.

d. an electron-pair acceptor.

A Lewis acid is:

a. a proton donor.

b. a proton acceptor.

c. an electron-pair donor.

d. an electron-pair acceptor.

What is the conjugate base of

HPO42- ?

a. H3PO4

b. H2PO41-

c. PO43-

d. HPO32-

What is the conjugate acid of

SO42- ?

a. H2SO4

b. HSO41-

c. SO32-

d. H3SO4+

The stronger the acid, the (X) its

conjugate base. Acids and bases

generally react to form their (Y)

conjugates.

a. X = stronger, Y = stronger

b. X = stronger, Y = weaker

c. X = weaker, Y = stronger

d. X = weaker, Y = weaker

What is the pH of a 0.0200 Maqueous solution of HBr ?

a. 1.00

b. 1.70

c. 2.30

d. 12.30

What is the pH of a 0.0400 Maqueous solution of KOH ?

a. 12.60

b. 10.30

c. 4.00

d. 1.40

The Ka of HF is 6.8 x 10-4. What

is the pH of a 0.0200 M aqueous

solution of HF ?

a. 1.70

b. 2.43

c. 3.17

d. 12.30

The Ka of HF is 6.8 x 10-4. What

is the pH of a 0.0400 Maqueous solution of KF ?

a. 2.28

b. 2.43

c. 6.12

d. 7.88

Which choice correctly lists the

acids in decreasing order of

acid strength ?

a. HClO2 > HClO > HBrO > HIO

b. HClO > HBrO > HIO > HClO2

c. HIO > HBrO > HClO > HClO2

d. HClO2 > HIO > HBrO > HClO

Which base is the weakest ?

• F–

• NH3

• OH–

• SO42–

• C2H3O2–

Which acid is the strongest ?

• H2O

• H3O+

• HF

• HC2H3O2

• NH4+

Which base is the strongest ?

• NO3–

• C2H3O2–

• HCO3–

• CO32–

• NH3

Acid Ka

If the pH = 2 for an HNO3 solution,

what is the concentration of HNO3?

• 0.10

• 0.20

• 0.010

• 0.020

• 0.0010

If the pH = 10 for a Ca(OH)2

solution, what is the concentration

of Ca(OH)2?

• 1.0 x 10–10

• 5.0 x 10–11

• 5.0 x 10–3

• 1.0 x 10–2

• 2.0 x 10–2a digital pH meter

A blue color will result when

bromthymol blue is added to an

aqueous solution of:

• NH4Cl

• KHSO4

• AlCl3• KH2PO4

• Na2HPO4

What is the pH of a 0.010 M HClO4

solution ?

• < 1

• 1

• 2

• 7

• > 7

What is the pH of a 0.010 M HF

solution ?

• < 1

• 1

• 2

• > 2

• 7

• H2S

• HF

• HCl

• HBr

• HI

Which acid is the strongest ?

Which base is the strongest ?

• ClO4–

• BrO3–

• BrO4–

• IO3–

• IO4–

When lithium oxide (Li2O) is dissolved in water, the

solution turns basic from the reaction of the oxide ion

(O2–) with water. Write the reaction that occurs, and

identify the conjugate acid–base pairs.

Answer: O2–(aq) + H2O(l) → OH–(aq) + OH–(aq).

OH– is the conjugate acid of the base O2–. OH– is also

the conjugate base of the acid H2O.

For each of the following reactions, use Figure 16.4 to

predict whether the equilibrium lies predominantly to

the left or to the right:

Answers: (a) left, (b) right

Calculate the concentration of OH–(aq) in a

solution in which (a) [H+] = 2 × 10–6 M;

(b) [H+] = [OH–];

(c) [H+] = 100× [OH–].

Answers: (a) 5 × 10–9 M, (b) 1.0 × 10–7

M, (c) 1.0 × 10–8 M

(a) In a sample of lemon juice [H+] is 3.8 ×10–4 M. What is the pH? (b) A commonly

available window-cleaning solution has

[OH–] = 1.9 ×10–6 M . What is the pH?

Answers: (a) 3.42, (b) [H+] = 5.3 ×10–9 M,so pH = 8.28

A solution formed by dissolving an

antacid tablet has a pH of 9.18.

Calculate [H+] .

Answer: [H+] = 6.6× 10–10 M

An aqueous solution of HNO3 has a pH

of 2.34. What is the concentration of

the acid?

Answer: 0.0046 M

What is the concentration of a solution

of (a) KOH for which the pH is 11.89;

(b) Ca(OH)2 for which the pH is

11.68?

Answers: (a) 7.8 × 10–3 M, (b) 2.4

×10–3 M

Niacin, one of the B vitamins, has the following

molecular structure:

A 0.020 M solution of niacin has a pH of 3.26. What is

the acid-dissociation constant, Ka, for niacin?

Answers: 1.5 × 10–5

A 0.020 M solution of niacin has a pH

of 3.26. Calculate the percent

ionization of the niacin.

Answer: 2.7%

The Ka for niacin (Practice Exercise

16.10) is 1.5 × 10-5. What is the pH of

a 0.010 M solution of niacin?

Answer: 3.41

The percent ionization of niacin (Ka =

1.5 × 10-5) in a 0.020 M solution is

2.7%. Calculate the percentage of

niacin molecules ionized in a solution

that is (a) 0.010 M, (b) 1.0 × 10-3 M.

Answers: (a) 3.9%, (b) 12%

(a) Calculate the pH of a 0.020 M solution

of oxalic acid (H2C2O4). (See Table 16.3

for Ka1 and Ka2.)

(b) Calculate the concentration of oxalate

ion [C2O42–] , in this solution.

Answers: (a) pH = 1.80 ,

(b) [C2O42–] = 6.4 × 10–5 M

A solution of NH3 in water has a pH of

11.17. What is the molarity of the

solution?

Answer: 0.12 M

(a) Which of the following anions has the largest

base-dissociation constant: NO2–, PO4

3–, or N3–?

(b) The base quinoline has the following structure:

Its conjugate acid is listed in handbooks as having

a pKa of 4.90. What is the base dissociation

constant for quinoline?

Answers: (a) PO43– (Kb = 2.4 × 10-2),

(b) 7.9 × 10-10

In each of the following, indicate which

salt in each of the following pairs will form

the more acidic (or less basic) 0.010 M

solution: (a) NaNO3, or Fe(NO3)3; (b) KBr,

or KBrO; (c) CH3NH3Cl, or BaCl2, (d)

NH4NO2, or NH4NO3.

Answers: (a) Fe(NO3)3, (b) KBr, (c)

CH3NH3Cl, (d) NH4NO3

Predict whether the dipotassium salt of

citric acid (K2HC6H5O7) will form an

acidic or basic solution in water (see Table

16.3 for data).

Answer: acidic